A porous polymer battery separator is provided that includes variable porosity along its length. Such battery separators can increase the uniformity of the current density within electrochemical battery cells that may normally experience higher current density and higher temperatures near their terminal ends than they do near their opposite ends. By disposing a variable porosity separator between the electrodes of an electrochemical cell such that its terminal end has a lower porosity than its opposite end, the transport of ions, such as lithium ions, through the separator can be more restricted in normally high current regions and less restricted in normally low current regions, thereby increasing the overall uniformity of current density within the battery cell. Variable porosity battery separators may be produced by a modified solvent exchange process. The process may include forming a polymer-containing film having a non-uniform thickness, selectively densifiying the film so that it has a non-uniform polymer concentration, and inducing variable porosity in the film.
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1. A method of making a thin polymeric separator having an open porous structure that, when placed between and in facial contact with a positive electrode and a negative electrode in an electrochemical cell and filled with an electrolyte solution, permits the flow of ions in the cell from one electrode through the separator to the other electrode, each electrode having a shape in plan view and an electrical contact, the method comprising:
a) forming a polymer-containing film having a non-uniform thickness across its width, the film comprising a polymer and a polymer solvent in which the polymer is soluble;
b) selectively densifying the polymer-containing film by changing the thickness of the film by different amounts across its width so that the polymer-containing film has a non-uniform polymer concentration across its width;
c) subjecting the film to a solvent exchange process in which the polymer solvent of the film is at least partially replaced with a non-solvent in which the polymer is not soluble, wherein the polymer of the polymer-containing film is precipitated to form a porous structure in the film, the porous structure comprising the precipitated polymer and having a porosity that varies across the width of the film; and
d) obtaining the thin polymeric separator from the film in a shape complementary to the shapes of the positive and negative electrodes such that the porous structure includes pores that are sized and can be arranged in the cell to permit higher ionic current flow through the separator at locations removed from the electrical contacts on the electrodes so as to more uniformly distribute ionic current flow through the separator over the whole facial area of the separator.
2. The method as recited in
the polymer concentration is higher at the first end that at the second end after step b).
3. The method as recited in
4. The method as recited in
5. The method as recited in
6. The method as recited in
7. The method as recited in
8. The method as recited in
10. The method as recited in
11. The method as recited in
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This disclosure pertains to separators for use between electrodes in electrochemical battery assemblies and, more specifically, to porous polymeric separators that both physically isolate opposing electrodes from one another and contain electrolyte to transport ions from one electrode to the other during battery charging and/or discharging cycles.
Battery separators are widely used in liquid-electrolyte batteries to prevent physical contact between positive electrodes and negative electrodes within a given battery cell while simultaneously enabling ionic transport between electrodes. One type of battery separator is a porous or microporous polymeric separator. This type of separator is typically placed between the positive and negative electrodes within an electrochemical battery cell to physically isolate the electrodes from one another and to absorb liquid electrolyte into its porous structure. By being in intimate physical contact with each electrode, the separator containing the liquid electrolyte facilitates ion transport through the pores of the separator and between electrodes during the operation of the battery, either while discharging under an electrical load or while charging under an applied voltage from an external source.
Depending on the particular application for a liquid-electrolyte battery, any number of individual battery cells may be arranged in series, in parallel, or in various combinations thereof to satisfy the power requirements for the application. For example, a given battery cell is usually capable of producing a known voltage, based largely on the types of materials utilized, and has a particular current capacity, based largely on the types of materials, the size of the components such as the electrodes and the surface area of the electrodes in contact with the electrolyte. To obtain the desired voltage from a battery, a sufficient number of individual cells are connected in series; e.g., six two-volt cells may be placed in series to obtain a twelve volt battery. To obtain the desired current capacity from the battery, multiple such sets of cells may be connected in parallel or multiple sets of cells connected in parallel may be connected in series. Of course other arrangements are possible.
In batteries that utilize multiple cells electrically connected to achieve usable power levels, one way that multiple electrodes of one polarity or the other can be connected to each another is via a common electrically conductive connection located along the same edge of each electrode. For example, individual electrodes sometimes each include a tab extending from a respective edge so that the multiple tabs of each polarity can be connected to one another by welding or some other suitable process to form an electrical connection between the individual electrodes. In some battery assemblies, such tabs extend from a top edge of each electrode or from a current collector associated therewith. Such internal battery connections may also be called internal terminals.
The inventors of the subject matter disclosed herein have recognized some potential problems that may result from battery constructions that include internal terminals such as those described above and have discovered structures and methods to help mitigate the problems.
Disclosed below are methods of making separators for use in electrochemical battery cells, such as lithium-ion battery cells. Such separators are quite thin (e.g., up to about 50 μm thick) and are placed between positive and negative electrodes in battery cells in facial contact with each of the electrodes. They may be in the form of polymeric sheets or films that are complimentary in shape with the electrodes. For example, some battery electrodes are rectangular in shape, and in a complimentary fashion, the separator films are rectangular in shape as well. The separators are characterized by an open porous structure within the separator material or materials. More specifically, the separator includes a series of pores distributed throughout the sheet along its length and width, the pores being interconnected such that they connect opposite surfaces of the film through its thickness. The pores permit liquid electrolyte flow and ion conduction through the separator.
The inventors herein have recognized that separators may be formed with a variation in the pore amount, size, and/or locations so as to provide for more uniform ionic current flow across the entire area of the separators and facing electrodes. According to the structures and methods presented below, this interconnected pore structure includes pores that may vary in size, number, spacing, and distribution along the length and/or width of the separator in a controlled manner, broadly defining a variable porosity. One end of each electrode and the complimentary-shaped separator in a battery cell typically lies in close proximity to an electrical contact of each electrode, usually in the form of metallic tabs that extend from each of the electrodes. Such tabs may join and be electrically connected to tabs from other electrodes and/or battery cells to form a common terminal. The variable porosity separators described below may be oriented in the cell so that the end of the separator furthest removed from the tabs has a higher porosity and more ionic conduction than the end of the separator located nearest the tabs. This type of configuration may be prepared to bring more uniformity to an otherwise non-uniform current density along the length of the electrodes by allowing higher levels of ion transport through the separator in the higher porosity regions furthest removed from the electrode tabs.
Taking advantage of the fact that the pores in a typical separator are included to hold a liquid electrolyte and to additionally allow flow of ions through the pores via the liquid electrolyte, the present inventors have discovered previously unknown methods of controlling the flow of ions through the pores by controlling the size and distribution of the pores, along with methods to control the size and distribution of the pores so that different sizes and distributions of pores may be present within the same separator. Using the methods described below, not only can the size and distribution of pores be controlled and varied within the same separator, but the location of the different-sized pores and corresponding variations in material porosity may also be controlled within an individual separator.
The inventive methods of making variable porosity separators may generally include producing a polymer-based film having a non-uniform thickness across its width, selectively densifiying the film so that it has a non-uniform polymer concentration across its width, and inducing porosity into the film via a solvent exchange process. The preparation and configuration of the film prior to the solvent exchange process, as described in the methods below, are previously unknown techniques. The polymer-based film may be a polymer solution, including a polymer, such as a polyimide, and a polymer solvent. The film may be deposited onto a moving substrate by extrusion or other techniques in a continuous process and so that the film has a non-uniform thickness across its width, which is transverse to the direction of extrusion. A cross-section taken across the width of the film includes a first end and a second end corresponding to opposite widthwise edges of the continuously deposited film, the first end being thicker than the second end. The selective densification may include preferential evaporation of solvent from the film where evaporation is favored at the first, thicker end of the film. Selective densification may alternatively include mechanical working of the film by a process such as calendaring. The selective densifiying results in a film of uniform thickness having a non-uniform polymer concentration across its width from the first to the second end, with higher polymer concentration at the first end. Then, the film is immersed in a non-solvent to remove the polymer solvent from the film, thereby precipitating a porous polymer film. Due to the non-uniform polymer concentration across the width of the film, the resulting film has a variable porosity, with the first, more dense end having lower porosity than the second, less dense end. The less densified areas of the film have larger and/or more pores for increased ionic conduction through the film in those areas in the presence of an electrolytic fluid.
Using these or other methods, an electrochemical battery cell may be produced according to a preferred embodiment. The electrochemical cell is preferably a lithium-ion cell and includes a positive electrode and a negative electrode with a porous separator assembled between the electrodes. The separator contains an electrolyte solution within its porous structure that is capable of transporting ions from one electrode to the other. The separator is preferably made using one or more polyimide and/or aromatic polymers and has a variable porosity. The porosity may vary such that the porosity and/or pore size is smaller near the portions of the separator lying near an electrode terminal and larger in separator regions spaced from or further removed from the terminal so that ionic flow through the separator during the operation of the electrochemical cell is more restricted near the terminal end than it is near the distant end. The terminal end of a typical rectangular separator and its corresponding rectangular electrodes within a cell is typically the upper end where the current density and temperature is highest within a cell. Relative restriction of the ionic flow in this region compared to the opposite or lower end of the cell causes the cell to operate with a more uniformly distributed current density and temperature profile, eliminating many of the problems associated with non-uniform current density.
Other objects and advantages of the invention will be apparent from a description of illustrative embodiments of the invention which follow in this specification. Reference is had to drawing figures which are described in the following section of this specification.
The following description of the embodiment(s) is merely exemplary in nature and is not intended to limit the invention, its application, or uses.
Embodiments of this invention include practices to form porous separators for use between opposing electrodes in electrochemical battery cells. Before further illustration of porous separators and the processes that may be used to form them, it may be helpful to illustrate a typical liquid-electrolyte battery environment in which the separator functions.
An exemplary and schematic illustration of a typical liquid-electrolyte battery 10 is shown in
Alternatively, any number of separators 18 within a cell may be included as portions of a continuous sheet or film of separator material that wraps around alternating vertical edges of each electrode to assume its functional position between each pair of electrodes. For example, in a battery such as that shown in
The positive and negative terminals 22 and 26 can be connected to an electrical device 28 as shown. In this example, the terminals 22, 26 are connected to an electrical load L that places the battery 10 into a discharge state. Alternatively electrical device 28 can be an external power source that places the battery 10 into a charging state. Electrical device 28 may be any number of known electrically-powered devices, including but not limited to an electric motor for an electric or hybrid vehicle, a laptop computer, a cellular phone, or a cordless power tool, to name but a few. The electrical device 28 may alternatively be a power-generating apparatus that charges the battery 10 for purposes of storing energy. For instance, the tendency of power generating devices such as wind-powered turbines and solar panel matrices to variably and/or intermittently generate electricity often results in a need to store surplus energy for later use. In some cases, electrical device 28 can itself double as an electrical load and a power-generating apparatus, as may be the case with electric motors of hybrid or electric vehicles, where the electric motors are utilized as battery-charging generators during vehicle deceleration, for example. Of course,
The inventors of the subject matter herein disclosed have recognized that by locating the electrical connection for the multiple electrodes along the same edge of each electrode, as shown and described in battery 10 of
An uneven distribution in the current density within the battery cells can have some potentially undesirable effects, such as poor utilization of the electrode materials; i.e., portions of the electrodes closer to the tabs or internal terminals experience more electrochemical activity over the life of the battery than portions that are further from the tabs or internal terminals. In some types of battery constructions, this can cause the electrodes to decay unevenly, causing the portions that experience the higher current density to decay at an accelerated rate, while portions that experience lower current density remain underused with additional life remaining in those portions after the high current density portions have decayed beyond their usefulness. Another undesirable effect of an uneven current distribution in battery electrodes is a corresponding uneven temperature distribution within the electrochemical cell, with the higher current density regions having an elevated temperature compared to lower current density regions. Elevated temperatures within a battery cell can have the effect of degrading the polymeric material of the separator, among other detrimental effects. Uneven current distribution may also result in non-uniform expansion and contraction of the solid electrode materials. For instance, conventional lithium ion cells may expand on charge and contract on discharge. Hence, a non-uniform current distribution may lead to mechanical strains and associated stresses on the cell materials that can lead to loss of contact between cell components and accelerate cell failure.
These are only a few examples of potentially undesirable effects of an uneven current density distribution within a battery cell. The effects may be amplified with larger batteries that are designed for large electrical current capacity, for example with larger automotive batteries (as compared to smaller batteries such as those used in portable electronics or the like). Larger batteries may generally have larger and/or longer electrodes, with the resulting disparity in current density from one end of the electrode plate to the other increasing with increasing electrode length or distance from the internal terminals. Temperature effects are even further amplified in larger batteries because the ratio of the mass of the battery to the surface area of the battery generally increases, making the cooling of the already thermally insulated system more difficult overall.
In a typical embodiment, separators 18 include one or more porous, microporous, or fibrous polymeric films that have a liquid electrolyte absorbed into their structure. Specific embodiments according to the teachings presented herein will be described in further detail below. But generally, separator 18 is designed to physically separate the positive and negative electrodes 14, 16 of each cell 12 from one another while simultaneously allowing ion transfer from one electrode to the other through the pores of the separator. The separator 18 facilitates such ion transfer by having its open structure filled with liquid electrolyte and by being in intimate contact with the surfaces of each of the opposing positive and negative electrodes 14, 16.
Battery 10 can additionally include a wide range of other components that, while not depicted here, are nonetheless known to skilled artisans. For instance, battery 10 may include a casing, gaskets, terminal caps, vents, fill ports, or any other desirable components or materials that may be situated between or around the positive electrodes 14, the negative electrodes 16, and/or the separators 18 for performance related or other practical purposes. Moreover, the size and shape of the battery 10 may vary depending on the particular application for which it is designed. Battery powered automobiles and hand-held consumer electronic devices, for example, are two instances where the battery 10 would most likely be designed to different size, capacity, and power-output specifications. The battery 10 may also be connected in series or parallel with other similar batteries to produce a greater voltage output and power capacity if the electrical device 28 so requires.
The exemplary battery construction depicted in
Lithium-ion batteries have gained favor in many applications due to their relatively high voltage or potential per cell, relatively high energy density (available power per unit mass), ability to maintain a charge while dormant for longer periods of time than other rechargeable batteries, and a reduced presence of the “memory” phenomenon that other types of rechargeable batteries may exhibit when subjected to multiple shallow-discharge and recharge cycles.
The operation of a lithium-ion battery is well-known by skilled artisans. In a lithium-ion battery, the negative electrode 16 typically comprises a lithium insertion material or alloy host material, the positive electrode 14 typically comprises a lithium-containing active material that can store lithium at higher potential (relative to a lithium metal reference electrode) than the host material of the negative electrode 16, and the liquid electrolyte contained in the porous separator is typically an electrolyte solution comprising one or more lithium salts dissolved and ionized in a non-aqueous solvent. Each of the positive and negative electrodes 14, 16 may also be carried on or connected to a metallic current collector—typically aluminum for the positive electrodes 14 and copper for the negative electrodes 16. For example, a typical positive 14 electrode may comprise a sheet of aluminum metal foil as the current collector and be coated on both sides with an electrode material comprising a layered structure of metal oxide, such as lithium cobalt oxide (LiCoO2), or a material comprising a tunneled structure, such as lithium manganese oxide (LiMn2O4). A typical negative electrode may comprise a sheet of copper metal foil as the current collector and be coated on both sides with an electrode material comprising a layered material such as a graphitic carbon.
A lithium-ion battery can generate a useful electric current during battery discharge by way of reversible electrochemical reactions that occur when electrical device 28 is an electrical load L connected between the positive terminal 22 and the negative terminal 26 at a time when the negative electrodes 16 contain a sufficiently higher relative quantity of intercalated lithium. The chemical potential difference between each positive and negative electrode 14, 16—approximately 3.7 to 4.2 volts in a lithium-ion cell, depending on the exact chemical make-up of the electrodes 14, 16—drives electrons produced by the oxidation of intercalated lithium at the negative electrode 16 through the electrical load L toward the positive electrode 14. Lithium ions, which are also produced at the negative electrode, are concurrently carried by the electrolyte solution through the porous separator 18 and toward the positive electrode 14. The electrons flowing through the electrical load L and the lithium ions migrating across the porous separator 18 in the electrolyte solution eventually reconcile and form intercalated lithium at the positive electrode 14. The electric current can be directed through the electrical load L until the intercalated lithium in the negative electrode 16 is depleted and the capacity of the battery 10 is thus diminished.
Some batteries, such as lithium ion batteries, can be charged or re-powered at any time by utilizing an external power source as electrical device 28 connected to the terminals of the battery 10 to reverse the electrochemical reactions that occur during battery discharge. In a lithium-ion battery, the connection of an external power source to the battery 10 compels the otherwise non-spontaneous oxidation of intercalated lithium at the positive electrode 14 to produce electrons and lithium ions. The electrons, which flow back towards the negative electrode 16 from the external power source, and the lithium ions, which are carried by the electrolyte across the porous separator 18 back towards the negative electrode 16, reunite at the negative electrode 16 and replenish it with intercalated lithium for consumption during the next battery discharge cycle. The external power source that may be used to charge the battery 10 may vary depending on the size, construction, and particular end-use of the battery. Some exemplary external power sources include, but are not limited to, an AC wall outlet and a motor vehicle alternator. Similar charge and discharge cycles may be described for other types of batteries where other types of metal ions are transported through the porous separator 18 from one electrode to the other, as the lithium-ion construction is only exemplary.
Referring again to
Separator layer 34 may be in the form of a film or sheet and may typically have an open porous structure throughout the material, including a series of interconnected pores that connect opposite surfaces of the separator layer to one another through the thickness of the separator layer to facilitate the transfer of ions therethrough when in use and filled with electrolyte. Examples of two exemplary porous structures are depicted in
The illustrated porous structures are only exemplary in nature, and any number of other types of porous structures may be provided or used in accordance with the methods described herein. For example, the porous structure may be a function of several variables of the solvent exchange process, such as the selected polymer-solvent system, the selected non-solvent, the concentration or polymer-solvent ratio, the presence of fillers in the film, or the pre-conditioning conditions, to name a few.
The solvent exchange process summarily described above may typically be used to form generally uniform porous structures within a separator layer 34. A particular porous structure may be characterized by several variables, including at least its porosity and its average pore size. Porosity may be defined as the volume percentage of the material that is occupied by voids or pores. For example, typical porosities for separator layers 34 may range from 20-90%, meaning that some separator layers 34 may include one or more regions having anywhere from 10-80% of its bulk volume composed of polymer matrix 36 and 20-90% of its bulk volume composed of pores 38. More commonly, the porosity of a typical separator layer 34 produced using the above process may range from 40-70%, and most commonly will range from 50-70%. Average pore size may be defined for a portion of a separator layer 34 as the average cross-sectional dimensions of the pores 38 within matrix 36. In most applications, an average pore size of less than 1 μm may be desirable, ranging for example from 0.01 to 1.0 μm. But average pore size can range up to 5 μm in some applications. Separator layer 34 may also be characterized by a layer thickness, which is generally uniform when formed into its final usable state and dimensions. The thickness of separator layer 34 typically ranges from about 15 to 30 μm, particularly when separator 18 is composed of a single separator layer 34. Overall separator 18 thickness may range up to about 50 μm, which may include a single separator layer 34 or multiple separator layers 34 that make up the overall thickness. Separator layers 34 can have thicknesses as low as about 10 μm in some high energy density applications, but a certain amount of strength and durability of the layer may be sacrificed with lower thicknesses. One embodiment of a separator 18 includes a single separator layer 34 having a thickness ranging from about 20 to 30 μm, and preferably about 25 μm.
Turning now to
In an exemplary process, step 42 generally includes forming a polymer-containing film having a non-uniform thickness. This step preferably includes an extrusion step whereby the desired separator layer polymer composition is first dissolved in a suitable polymer solvent and then extruded onto a substrate. The substrate may be a moving substrate such as a conveyor or carrier belt to move along with and support the extruded film. The substrate may be made from any of a variety of suitable materials, including polymeric materials or non-polymeric materials such as metals, ceramics, glass, etc., so long as the substrate surface is smooth so as not to substantially affect the porous structure to be introduced in subsequent steps. In some embodiments, however, the substrate may be wetted with a non-solvent prior to extruding the polymer solution thereon in order to allow selective porosity changes in the film from the underside of the film that may not have complete access to the non-solvent in subsequent steps.
Referring to portions of
A preferred polymer for the polymer-solvent system may be selected from the polyimide family of polymers. Aromatic polymers are another preferred type of polymers. It may also be preferable that the repeating unit of the polymer include one or more sulfur atoms, one or more nitrogen atoms, or at least one of each. Such materials may be preferred for their high strength, even when having a high level of porosity, and for their high temperature stability, to name a few advantageous properties that may be useful in liquid-electrolyte battery applications. Accordingly, a preferred polymer may be an aromatic polyimide. One example of a suitable aromatic polyimide is polyetherimide (PEI). Some other exemplary polymers that may be suitable include polyamide-imide, polysulfone, polyethersulfone, and polyamide. Other polymers may of course be selected based on any of the criteria listed above regarding polymer material properties or based on other criteria. Additionally, the polymer-solvent system may include more than one polymer or copolymers that include suitable polymers.
The polymer solvent is selected based on its ability to dissolve the selected polymer or polymers. The polymer solvent should also be miscible with the selected non-solvent to be used in the subsequent solvent exchange step. Some polymer solvents that may be included in the polymer-solvent system are dimethyl sulfoxide (DMSO), dimethylformamide (DMF), N-methylpyrrolidone (NMP), and acetonitrile. More than one polymer solvent may be included in the system so long as the polymer components are soluble in the polymer solvent mixture. The concentration of the polymer solution may range from about 5 to 40% by weight as the polymer component. In one embodiment, the polymer component is about 20 wt % of the solution. In a preferred embodiment, the polymer solution includes a polyimide dissolved in DMSO at a concentration of about 20 wt %. Of course, other polymer concentrations outside of these ranges may be used, depending on multiple variables and processing parameters such as viscosity, solvent volatility, polymer molecular weight, etc.
In some embodiments, one or more optional ceramic or other type of particulate filler, such as silica, alumina, calcium carbonate, and titanium oxide, that have particle sizes of less than 10 μm may be suspended in the polymer-containing film to help improve the mechanical and electro-chemical performance of the resulting separator layers. Where included, such filler loading can be anywhere from 1%-90% by weight.
Other techniques may be used to produce a polymer-containing film having a non-uniform thickness. For example, film 34′ may be deposited onto substrate 50 via a spray process similar to painting, where the film is applied thicker in cross-section at first end 30′ than at second end 32′, for example by metering a greater amount of polymer solution near the first end than near the second end. Other techniques may include a casting process, an injection/roll compaction process, or a slot die coating system with a non-uniform opening. The film thickness may be applied non-uniformly by shifting the angle of a doctor blade or compaction rollers, for example.
Referring again to
In an exemplary embodiment, the polymer concentration is uniform throughout the film 34′ at the beginning of step 44, ranging from 5-40% polymer by weight and preferably about 20% polymer by weight. At the completion of step 44, the polymer concentration at first end 30′ may range from about 5-40% polymer by weight and preferably about 25% polymer by weight, while the polymer concentration at second end 32′ may range from about 15-60% and preferably about 40% polymer by weight. These concentration changes across the width of film 34′ may vary depending on several factors, including the desired change in thickness prior to step 46, discussed in more detail below.
In one embodiment, illustrated in
The rate of evaporation of polymer solvent from exemplary film 34′ may be affected by several variables, such as temperature, pressure (of the surrounding atmosphere), overhead fluid flow rate, solvent vapor pressure, polymer concentration, or other factors. By controlling and varying one or more of these variables across the width of the film 34′, evaporation rates across the width of the film can be controlled to bring the film 34′ to a non-uniform polymer concentration and a corresponding thickness distribution across its width. For example, the film 34′ may be placed in a chamber 52 having a variable overhead space 54. The chamber 52 may be a closed chamber that can house individual films 34′, or it may be a chamber through which a continuous film 34′ can pass, supported by a moving substrate 50 such as a conveyor. Variable space 54 is provided in chamber 52 as a space in which one or more of the above variables affecting evaporation rate can be controlled. Variable space 54 may include a first and second end 56, 58 corresponding to first and second ends 30′, 32′ of film 34′ and may be located above the film 34′ and substrate carrier 50. In one embodiment, variable space 54 may have a non-uniform temperature profile such that first end 56 is controlled to have a higher temperature than second end 58, with a controlled temperature gradient between the two ends 56, 58. Separately controlled heaters or other types of variable heat sources may be used along the width of the variable space to provide the non-uniform temperature profile. Suitable temperatures widely vary, depending on the type of solvent in the film and other factors. In one embodiment, the temperature gradient is provided beneath the film 34′ to avoid the formation of a skin layer on top of the film. This type of temperature control, while from beneath the film, still results in a variable overhead space where vapor pressures above the film are varied by the temperature profile provided beneath the film.
In another embodiment, variable space 54 may provide a non-uniform pressure profile such that a lower pressure region is provided at first end 56 than at second end 58, with a gradient provided between the two ends. For example, a series of separately controlled vacuum units or a vacuum nozzle having a non-uniform orifice may be used along the width of the variable space to provide the non-uniform pressure profile, in which the various pressure regions may be localized near the film 34′ across its width. In another exemplary embodiment, the flow rate of an ambient fluid, such as air, flowing through space 54 may be selectively controlled. For instance, the ambient fluid may generally travel in the extrusion direction over the film 34′ such that the flow rate is higher at the first end 56 of the space than at the second end 58 of the space 54, with a gradient in flow rate between the ends. This non-uniform ambient fluid flow rate may be provided, for example, by a series of fans or blowers arranged to provide the desired flow profile over film 34′. Other techniques of controlling ambient fluid flow rate are possible, and ambient fluids other than air may be utilized.
One or more of these or other exemplary variable space configurations may also be combined. For example, a non-uniform ambient fluid flow rate may be provided in the variable space 54 where the temperature of the ambient fluid is also non-uniform from one end of the space to the other. For instance, warmer, faster moving air may be forced to flow over the first end 30′ of film 34′, while cooler, slower air may be forced to flow over the second end 32′, with gradients of each of the flow rate and the temperature between the two ends. In other embodiments, one variable such as temperature may be controlled from beneath the film 34′ and substrate 50, and/or another variable such as pressure may be controlled from above the film 34′. It is also possible to entirely eliminate the chamber in some applications, providing non-uniform temperature, pressure, and/or flow rate profiles over film 34′ using the associate equipment outside of a chamber environment. But chamber 50 may provide the additional advantage of controlling other process variables besides those being used to preferentially evaporate solvent from the polymer-containing film. In all of the above exemplary embodiments of variable space 54, evaporation is favored at the thicker portions of the film, thus densifiying the film such that a non-uniform polymer concentration across the width of the film is obtained, along with a different non-uniform thickness profile than that at the beginning of step 44. As indicated at the bottom of
This type of thickness profile may be desirable due to the nature of the subsequent solvent exchange process. A typical solvent exchange process will cause an overall shrinkage of the film, including a reduction in its thickness. The amount of shrinkage, and thus the amount of reduction in thickness, is a function of polymer concentration in the film, among other variables. Because exemplary process 40 introduces a non-uniform polymer concentration across the width of film 34′ in step 44, the shrinkage across the width of the film during solvent exchange will be non-uniform as well. In particular, higher polymer concentration generally results in less shrinkage while lower polymer concentration generally results in more shrinkage. Therefore, for step 46 to result in a film having a uniform thickness across its width, the higher polymer concentration portion of film 34′, in this case second end 32′, should be thinner than the lower polymer concentration portion, such as first end 30′.
In another exemplary embodiment of step 44, illustrated in
In an exemplary pre-conditioning process, the polymer-containing film is subjected to an environment including a non-solvent, as previously defined in the summary description of a solvent exchange process. Preferred non-solvents include water, various alcohols, and blends thereof, though any non-solvent that is miscible with the polymer solvent and will not dissolve the polymer may be used. As a pre-conditioner, the non-solvent is preferably in vapor form, limiting the uptake of the non-solvent by the polymer solution film so that complete solvent exchange does not occur prematurely. The pre-conditioning process partially solidifies the polymer solution into a gel-like film, though it does not change the relative dimensions of the film 34′; i.e., the polymer-containing film having a non-uniform thickness retains its non-uniform thickness during pre-conditioning. In a non-limiting example of a preconditioning process, film 34′ may enter a chamber 60 that includes a space 62 including a non-solvent, sometimes mixed with polymer solvent, in vapor form. Chamber 60 may be a closed chamber or a flow-through chamber that allows film 34′ to move through the space 62, carried by substrate 50. A preferred non-solvent may be water, and the relative amount of water vapor in space 62 is measured as relative humidity. In one embodiment, the relative humidity in space 62 is maintained at or above 50%, and the exposure time ranges from about 1 second to about 15 minutes. In other embodiments, the relative humidity is maintained at about 75% or up to about 95%. The combination of humidity and exposure time should be selected so that the film is sufficiently solid to undergo mechanical working. During the conversion of the polymer solution from a liquid-like to a gel-like state, porosity of the film may be initiated in the form of uniformly distributed pore sites and/or pores throughout the film, though by terminating the pre-conditioning process when the film obtains sufficient solidification for mechanical working, any pores formed may be generally too small to be useful in a battery separator.
After the pre-conditioning process, mechanical working of the film 34′ may proceed. Film 34′, and optionally substrate 50, may be driven through one or more pairs of rollers 64 to bring film 34′ to a uniform thickness across its width. Similar to the preferential evaporation process previously described, film 34′ is densified to a greater extent at first end 30′—the thicker end—than at second end 32′. Preferentially compressing film 34′ in this manner thus both evens out the thickness of the film across its width, and increases the polymer concentration or film density in the areas of greater compression (the formerly thicker areas). As with the preferential evaporation process, the film 34′ is densified such that a non-uniform polymer concentration is obtained across the width of the film. In this case, however, a uniform film thickness is also obtained and is preferable. Because of the pre-conditioning of the film to bring it to a gel-like form, the shrinkage in the subsequent solvent exchange step is more uniform than with the non-pre-conditioned film as described in conjunction with
Step 46 generally includes inducing porosity in the film and is preferably accomplished via a solvent exchange process, also known as a phase inversion process. Simply stated, the solvent exchange process includes immersing the polymer-containing film in a bath containing a non-solvent, such as water or alcohol, as non-limiting examples. The bath may also contain a mixture of polymer solvent and non-solvent which, among other things, may affect the kinetics of the solvent exchange process. Typically, the film, such as exemplary film 34′, is immersed in a coagulation bath including the selected non-solvent. As previously noted, the non-solvent should be miscible with the polymer solvent for the exchange process to work effectively. Individual films on their respective substrates may be placed into the coagulation bath, or the bath may be arranged such that a continuously moving film and substrate can make its way through the bath. In the solvent exchange process, the polymer solvent, miscible with the bath of non-solvent in which it is immersed, begins to leave the film 34′ to mix with the non-solvent bath, being continuously replaced in the film 34′ with non-solvent. As this exchange of polymer solvent for non-solvent transpires within the film, the solvent within the film changes in composition from pure polymer solvent to a mixture of polymer solvent and non-solvent, with the percentage of non-solvent continuously increasing. Thus, the solubility of the polymer is negatively affected, and the polymer begins to precipitate out of solution when the non-solvent becomes a sufficiently high percentage of the solvent within the film 34′. Eventually, the non-solvent substantially replaces all of the polymer solvent within the film and a porous film of the polymer, saturated in non-solvent, results.
While solvent exchange processes such as this may typically be used to form porous films from polymer solution films, utilizing such a process with selectively densified films 34′ produced via the above-described processes—more particularly, films having a non-uniform polymer concentration across their width—is previously unknown. The result of using the described solvent exchange process on such films 34′ is an obtainable separator layer 34 (such as that for use in the battery 10 of
In an exemplary embodiment of separator 34 produced according to the above-described methods, the resulting porosity near the terminal end 30 of separator layer 34 may range from 20-88% and the resulting porosity near the opposite end 32 may range from 22-90%. More preferably, the porosity near the terminal end 30 ranges from 40-78% and the porosity near the opposite end 32 ranges from 42-80%. In one embodiment, separator layer 34 has a gradually increasing porosity from the terminal end 30 to the opposite end 32, where the porosity near the terminal end is at least 20% and the porosity near the opposite end is at least 22%. In yet another embodiment, the difference between the porosity near the terminal end and the porosity near the opposite end is at least 2% porosity. Preferred pore sizes are less than 1 μm at both ends of the resulting separator layer, but may be larger at the opposite end 32 than they are at terminal end 30, in one embodiment being at least 5% larger. In another embodiment, average pore sizes near the terminal end 30 are less than 1 μm, and average pores sizes near the opposite end 32 are greater than 1 μm. In yet another embodiment, separator layer 34 has a gradually increasing pore size from the terminal end 30 to the opposite end 32, where the average pore size near the terminal end is less than 1 μm and the average pore size near the opposite end is at least 5% greater than the pore size at the terminal end. Of course, process variables may be adjusted to obtain pore sizes and porosities outside of these ranges, depending on the particular application.
Separator layers 34 having variable porosity as may be produced by this or other exemplary processes can help alleviate some of the potentially undesirable effects described earlier that may be caused by non-uniform current densities within electrochemical battery cells. Such separator layers having variable porosity can help alleviate these potentially undesirable effects by helping to eliminate the actual cause of the effects; namely, the non-uniform current density along a given electrode and within its corresponding battery cell or cells. For example, separators 18 in
Of course, the above-described processes are only exemplary and may include additional process steps, omit certain steps, and/or include modified steps, depending on the desired final separator layer configuration and structure. For example, in selective densifiying embodiments that include mechanical working, the working may be performed in the coagulation bath, usually near the beginning of the bath in a continuous process while the film is in a gel-like state and before it is fully solidified or precipitated. In such an embodiment, it may be possible to eliminate the pre-conditioning process. In other embodiments, the film may be partially worked prior to entering the coagulation bath and further worked in the bath. In another embodiment, the pre-conditioning step may be used in combination with preferential evaporation, either before or after the evaporation process or both before and after. For example, pre-conditioning prior to the preferential evaporation step may help to provide more controlled (slower) evaporation, while pre-conditioning after the evaporation step may help to control the resulting pore size, structure or morphology during the solvent exchange process. Additionally, multiple densifiying techniques may be combined, such as in processes including preferential evaporation and mechanical working as selective densification techniques. In one embodiment, an additional process step that may include stretching the resulting film in one or more directions may be added. Though not usually necessary following solvent exchange processes, stretching the film can help to increase pore size and/or porosity for certain applications.
It is also noteworthy that the above processes, terminology, and the order of the process steps may be described differently but remain within the scope of the teachings herein presented. For example, another way to describe the pre-conditioning process previously described is to include it as a part of the solvent exchange process, because the pre-conditioning process includes limited solvent exchange. For example, pre-conditioning followed by mechanical working followed by solvent exchange may be viewed as a single solvent exchange process interrupted by mechanical working or as a solvent exchange process in which mechanical working of the film is included.
In additional variations, the polymer film 34′ produced in step 42 of process 40 may have a non-uniform thickness other than that indicated in
Such polymer-based films having controllable, variable porosity may additionally find other applications in the battery art, and are certainly not limited to use as battery separator layers, as controlled porosity may be useful for other battery applications besides controlling ionic transport between electrodes. Controllable, variable porosity films may even find useful applications outside the battery art, such as in fuel cells or in fluid filtration applications, for example.
While preferred embodiments of the invention have been described as illustrations, these illustrations are not intended to limit the scope of the invention.
Verbrugge, Mark W., Huang, Xiaosong, Kia, Hamid G.
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